1. Representational Analysis of Extended Disorder in Atomistic Ensembles Derived from Total Scattering Data
- Author
-
James R. Neilson and Tyrel M. McQueen
- Subjects
pair distribution function analysis ,Physics ,Crystallographic point group ,Condensed Matter - Materials Science ,extended disorder ,Basis (linear algebra) ,Scattering ,Momentum transfer ,Materials Science (cond-mat.mtrl-sci) ,FOS: Physical sciences ,atomistic ensembles ,Pair distribution function ,modeling ,Reverse Monte Carlo ,16. Peace & justice ,Research Papers ,General Biochemistry, Genetics and Molecular Biology ,Crystallography ,Symmetry breaking ,Statistical physics ,Basis set - Abstract
Representational analysis is used to characterize correlated short-range order in large atomistic ensembles. This method, analogous to tight-binding methods, enables the extraction of relevant structural parameters in an orthogonal and local basis that permits robust statistical analysis of crystalline disorder., With the increased availability of high-intensity time-of-flight neutron and synchrotron X-ray scattering sources that can access wide ranges of momentum transfer, the pair distribution function method has become a standard analysis technique for studying disorder of local coordination spheres and at intermediate atomic separations. In some cases, rational modeling of the total scattering data (Bragg and diffuse) becomes intractable with least-squares approaches, necessitating reverse Monte Carlo simulations using large atomistic ensembles. However, the extraction of meaningful information from the resulting atomistic ensembles is challenging, especially at intermediate length scales. Representational analysis is used here to describe the displacements of atoms in reverse Monte Carlo ensembles from an ideal crystallographic structure in an approach analogous to tight-binding methods. Rewriting the displacements in terms of a local basis that is descriptive of the ideal crystallographic symmetry provides a robust approach to characterizing medium-range order (and disorder) and symmetry breaking in complex and disordered crystalline materials. This method enables the extraction of statistically relevant displacement modes (orientation, amplitude and distribution) of the crystalline disorder and provides directly meaningful information in a locally symmetry-adapted basis set that is most descriptive of the crystal chemistry and physics.
- Published
- 2015